Development and some histochemical aspects of foliar glandular trichomes of
Stevia
rebaudiana
(Bert.) Bert. - Asteraceae
WALKYRIA ROSSI MONTEIRO
1, MARÍLIA DE MORAES CASTRO
2,5, SOLANGE CRISTINA
MAZZONI-VIVEIROS
3, and PAUL GORDON MAHLBERG
4(received: February 14, 2001; accepted: June 20, 2001)
ABSTRACT - (Development and some histochemical aspects of foliar glandular trichomes of Stevia rebaudiana (Bert.) Bert. - Asteraceae). The ten-celled biseriate glandular trichome of Stevia rebaudiana (Bert.) Bert.-Asteraceae, found on both leaf
surfaces, originates from a single protruding, protodermal cell undergoing an anticlinal division. A subsequent series of periclinal divisions, occurring in acropetal sequence, leads to the formation of the trichome, composed of five pairs of cells, one pair of basal cells, another of stalk cells and three pairs of secretory head cells. Developing, still two-celled glandular trichomes already occur on leaf primordia of the second pair (these primordia measuring, in some cases, ca. 0.30 mm in length), and most of the glandular trichomes are at the mature phase on very young, expanding leaves, for example on those of the sixth pair. The secretory material released by the head cells is stored in the trichome cavity (subcuticular space). Basic histochemical tests reveal that such material is lipophilic (mainly) and hydrophilic in nature.
RESUMO - (Desenvolvimento e alguns aspectos histoquímicos de tricomas glandulares decacelulares bisseriados de Stevia rebaudiana (Bert.) Bert.-Asteraceae). O tricoma glandular decacelular bisseriado de Stevia rebaudiana (Bert.) Bert.-Asteraceae, encontrado em ambas as superfícies da folha, origina-se a partir de uma célula protodérmica protuberante que sofre uma divisão anticlinal. Uma subseqüente série de divisões periclinais, ocorrendo em seqüência acrópeta, leva à formação do tricoma, composto por cinco pares de células: um par de células basais, um outro de células pedunculares e três pares de células secretoras da cabeça. Tricomas glandulares em desenvolvimento, ainda com duas células, já ocorrem em primórdios foliares do segundo par (estes primórdios medindo, em alguns casos, cerca de 0,30 mm em comprimento) e, em sua maioria, estão em fase madura em folhas muito jovens, ainda em expansão, como naquelas do sexto par. O material de secreção, liberado pelas células da cabeça, é armazenado na cavidade do tricoma (espaço subcuticular). Testes histoquímicos básicos revelam que, em sua natureza, tal material é lipofílico (principalmente) e hidrofílico.
Key words - Stevia rebaudiana, Asteraceae, glandular trichomes, ontogeny, histochemistry
Introduction
Stevia rebaudiana (Bert.) Bert. (Asteraceae) is
native to Paraguay and neighboring Brazilian border
(Monteiro 1982). It produces stevioside (a
diterpenoid tetracyclic glycoside), a noncaloric
sweetener considered to be 100-400 times as sweet
as sucrose (Felippe 1977, Handro & Ferreira 1989,
Kinghorn & Soejarto 1991). Nephrotoxicity is thought
to be caused by stevioside in studies on rats
(Toskulkao
et al. 1994, Melis 1995).
In experiments performed by Zaidan et al. (1980)
on vegetative organs (including roots) and
reproductive organs of S. rebaudiana plants, the
stevioside was obtained from leaf (the most
productive organ), stem and inflorescence.
Results from some morphological, structural,
ultrastructural, histochemical, and even biochemical
studies, carried out on glandular trichomes of many
species of Asteraceae, aided in characterizing the
trichome and its secretory material (Carlquist 1958,
1959a, Schnepf 1969, Vermeer & Peterson 1979a, b,
Karrfalt & Kreitner 1980, Kelsey & Shafizadeh 1980,
Werker & Fahn 1981, 1982, Ascensão & Pais 1982,
Ascensão & Pais 1985, Cappelletti et al. 1986,
Ascensão & Pais 1987, Duke & Paul 1993, Duke et al.
1994, Werker et al. 1994, Afolayan & Meyer 1995,
Corsi & Nencioni 1995, Ferreira & Janick 1995); only
a few of the structural studies include ontogenetic
aspects. Results from the observations on the
1. Universidade de São Paulo, Instituto de Biociências,Departamento de Botânica, Caixa Postal 11461, 05422-970 São Paulo, SP, Brasil.
2. Universidade Estadual de Campinas, Instituto de Biologia, Departamento de Botânica, Caixa Postal 6109, 13083-970 Campinas, SP, Brasil.
3. Secretaria de Estado do Meio Ambiente, Instituto de Botânica, Seção de Anatomia e Morfologia, Caixa Postal 4005, 01061-970 São Paulo, SP, Brasil.
4. Indiana University, Department of Biology, Bloomington, Indiana 47405, USA.
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W.R. Monteiro et al.: Foliar glandular trichomes of Stevia rebaudiana
glandular trichomes of Asteraceae have proved to
be important contributions to some taxonomic and/
or phylogenetic questions (Carlquist 1959a, Narayana
1979, Maleci & Marchi 1983, Kelsey 1984, Spring 1991,
Hellwig 1992, Castro et al. 1997). In addition, the
material produced by the glandular trichome is
interpreted to function in ecological roles in many
species (Levin 1973, Fahn 1979, Kelsey et al. 1984,
Duffey 1986, Wagner 1991, Duke 1994).
The objectives of this report are to: 1) describe
the development of the ten-celled biseriate glandular
trichome, of abundant occurrence on leaves of S.
rebaudiana, and 2) apply some routine histochemical
techniques to this gland to obtain information on the
chemical nature of its secretory product.
Material and methods
Plants were grown from seeds in a greenhouse of the Department of Biology, Indiana University, Bloomington, U.S.A. Seeds were supplied by the Instituto de Botânica, São Paulo City, SP, Brazil.
Plants were grown at about 25 °C, under continuous long-day conditions (16 h photoperiods) to be maintained in vegetative state, since S. rebaudiana is a photoperiodic
short-day flowering plant (Válio & Rocha 1977).
Vegetative shoot apices and different regions of fully expanded young leaves were fixed in FAA (Lersten & Curtis 1988) for 24 h, Lillie’s buffered neutral formalin (Clark 1981a) for 65 h, and formalin-ferrous sulphate reagent (Johansen 1940) for 48 h. Before dehydration the samples fixed in Lillie’s buffered neutral formalin and those fixed in formalin-ferrous sulphate reagent were washed for 2 h in 9 and 5 respectively, changes of deionized water. All samples were dehydrated through a tertiary butyl alcohol series, embedded in paraffin and then sectioned (Johansen 1940). Serial transections and longisections of shoot apices, and serial transections of samples taken from leaves, were cut at 5 µm thickness on a rotary microtome.
Fresh, freehand transections of expanding, and fully expanded young leaves were also obtained for study.
Sections from samples fixed in FAA were stained with tannic acid-iron chloride, Safranin and Fast green (Schneider 1981) for regular histological observations.
Paraffin sections from samples fixed in formalin-ferrous sulphate reagent were only deparaffinized (Johansen 1940) in order to reveal the histochemical localization of phenolic substances.
Besides the treatment with the formalin-ferrous sulphate reagent, other histochemical procedures were performed to detect: insoluble carbohydrates in samples fixed in FAA by the periodic acid-Schiff’s (PAS) test (Jensen 1962), the control being made by omission of treatment with periodic acid (Riding & Gifford 1973); pectinaceous materials in samples fixed in Lillie’s buffered neutral formalin by staining with Alcian blue 8GS (Clark 1981b); pectinaceous materials by staining freehand sections with Ruthenium red (Jensen 1962); lipids by staining freehand sections with Sudan black B (Jensen 1962).
Photomicrographs were taken with a Zeiss III photomicroscope.
Results
Developmental aspects - After enlarging and
protruding above the leaf surface, a single
protodermal cell (figure 1) undergoes an anticlinal,
symmetric division, resulting in the trichome two-cell
stage (figure 2). Both cells divide periclinally to form
the four-cell stage (figure 3). This stage is followed
by the six- (figures 4, 5), eight- (figure 6), and ten-cell
(figure 7) stages, resulting from a periclinal division
taking place in the upper cells of the four-, six-, and
eight-cell trichomes, respectively. These cells do not
appear to divide synchronously in the passage from
one stage to another. The trichome of figure 4 has
three cells in its right half and, still, two cells in the
left half; that of figure 6 has already four cells in its
left half, while the upper cell in the three-celled right
half is still dividing.
After reaching the ten-cell stage, the trichome
expands and differentiates. In face view, a mature
trichome (figure 8) is composed of five pairs of cells:
one pair of basal cells, another of stalk cells, and
three pairs of secretory head cells. Figures 9 and 10
show the trichome in lateral view with the presence
of translucent, vertically elongated areas interspersed
in the walls of the head cells. In mature trichomes
(figures 10, 11), secretory materials are accumulated
in the trichome cavity (subcuticular space), which
possesses a surface sheath (secretory sheath). This
sheath, lightly stained in figure 8, is clearly visible in
figures 10 and 11.
Figures 1-11. Stevia rebaudiana (Bert.) Bert. Developing and mature glandular trichomes, seen in longisections (1-7, 11) and
352
W.R. Monteiro et al.: Foliar glandular trichomes of Stevia rebaudiana
Figures 17 - 22. Stevia rebaudiana (Bert.) Bert. Mature glandular trichomes seen in transections of leaves. Histochemical
354
W.R. Monteiro et al.: Foliar glandular trichomes of Stevia rebaudiana
one-cell stage. It may also be, however, at the
two-cell stage in a lateral view of the trichome, since such
a view, also shown by figures 9 and 10, seemed to be
more frequent than the face view in the transections
of the shoot apices.
On fully expanded mature leaves the glandular
trichomes occur in a sparse distribution. Some
histochemical aspects of mature trichomes - In the
secretory sheath, a distinct staining is detected after
treatment with Sudan Black B (figure 17), Ruthenium
red (figure 18), Alcian blue 8GS (figure 19) and a light
staining with the PAS test (figures 8, 20). The latter
two dyes and the PAS test also stain the upper walls
of the apical head cells subtending the trichome cavity
(figures 18-20).
Secretory material collected in the trichome cavity
stains intensely with Sudan black B (figure 17), and
moderately with Ruthenium red (figure 18) and the
PAS test. The staining resultant from the latter
appears to be more expressive in materials seen along
the top of the trichome apical head cells (figure 20).
Secretory material of the trichome cavity also stains
with Alcian blue 8GS, although in a discreet way
(figure 19).
Contents of the head cells show a positive
reaction to treatment with Sudan black B (figure 17).
Starch grains become intensely stained when treated
with the PAS test (figure 21). Contents of the head
cells are also stained in material fixed in
formalin-ferrous sulphate reagent (figure 22).
Discussion
Previous studies confirm, as reported by
Carlquist (1958, 1959a, b), that the biseriate type of
glandular trichome is common in the Asteraceae
family, occurring in species belonging to different
tribes: Anthemideae (Vermeer & Peterson 1979a, b,
Kelsey & Shafizadeh 1980, Ascensão & Pais 1982,
Maleci & Marchi 1983, Ascensão & Pais 1985,
Cappelletti et al. 1986, Ascensão & Pais 1987, Jordaan
& Kruger 1992, Duke & Paul 1993, Werker et al. 1994,
Corsi & Nencioni 1995, Ferreira & Janick 1995),
Astereae (Hellwig 1992, Castro et al. 1997), Cardueae
(Schnepf 1969), Eupatorieae (Castro et al. 1997),
Heliantheae (Carlquist 1958, Castro et al. 1997),
Inuleae (Werker & Fahn 1981, 1982, Castro et al. 1997),
Mutisieae (Castro et al. 1997) and Vernonieae
(Narayana 1979, Castro et al. 1997). In S. rebaudiana,
like in other species of the genus Stevia (Castro et al.
1997), the ten-celled biseriate glandular trichome is
found on both leaf surfaces.
There are, however, few ontogenetic studies on
glandular trichomes in Asteraceae, and these relate
to only twelve species: Adenothamnus validus,
Blepharizonia plumosa,
Hemizonia fitchii,
H.
minthornii,
Holozonia filipes,
Madia sativa
(Carlquist 1958), Chrysanthemum morifolium cv.
Dramatic (Vermeer & Peterson 1979a, b),
Adenocaulon bicolor Hook. (Karrfalt & Kreitner
1980), Inula viscosa (L.) Ait. (Werker & Fahn 1981),
Artemisia crithmifolia (Ascensão & Pais 1982), A.
campestris L. ssp. maritima (Ascensão & Pais 1985,
1987) and A. annua L. (Duke & Paul 1993).
The ontogenetic development of the biseriate
glandular trichome of S. rebaudiana occurs in an
acropetal sequence (Uphof 1962), and is similar to
that reported by Vermeer & Peterson (1979a, b),
Ascensão & Pais (1982, 1985, 1987), as well as by
Duke & Paul (1993). This ontogeny also characterizes
the earliest developmental phases of glandular
trichomes of some species studied by Carlquist
(1958). In S. rebaudiana the first division of the gland
mother cell is anticlinal. For the glandular trichomes
of Helichrysum aureonitens Sch. Bip. on the other
hand, such a division is reported to be periclinal
(Afolayan & Meyer 1995).
In S. rebaudiana, fully differentiated functional
glandular trichomes are already present at early
stages of leaf development; in addition these glands
are formed only on leaf primordia and very young
leaves at various stages of differentiation. This is
similar to what has been stressed for lipophilic
trichomes of other species (belonging to various
families, including Asteraceae), such as: Beyeria
viscosa (Labill.) Miq. (Dell & McComb 1974),
Eremophila fraseri F. Meull (Dell & McComb 1977),
Inula viscosa (L.) Ait. (Werker & Fahn 1981) and
Artemisia campestris ssp. maritima (Ascensão &
Pais 1987).
test, regularly used to detect insoluble carbohydrates,
can also stain pectinaceous material (Holloway 1982).
These histochemical results will be related to the
ultrastructure of the S. rebaudiana glandular
trichome, and the origin of the trichome cavity in a
forthcoming article. The present study suggests that
the detachment of the secretory sheath from the
trichome apical head cells occurs along a zone
possibly containing pectin (Holloway 1982).
Histochemical characterization of the secretion
products in biseriate glandular trichomes has been
performed on nine species of Asteraceae: Artemisia
nova Nelson (Kelsey & Shafizadeh 1980), A.
umbelliformis Lam. (Cappelletti et al. 1986), A.
campestris ssp. maritima (Ascensão & Pais 1987),
A. dracunculus L. (Werker et al. 1994), A. nitida
Bertol. (Corsi & Nencioni 1995), Chrysanthemum
morifolium cv. Dramatic (Vermeer & Peterson 1979b),
Inula viscosa (L.) Ait., I. crithmoides L. and I.
graveolens (L.) Desf. (Werker & Fahn 1981, 1982).
In S. rebaudiana, the result from Sudan black B
treatment indicates that the secretory material
amassed in the trichome cavity is lipophilic. It also
appears to be hydrophilic, since it stains with
Ruthenium red (mainly) and the PAS test. With the
latter the staining seems to be more evident on the
material lying on the top of the trichome apical head
cells.
In biseriate glandular trichomes of the other
species of Asteraceae, the results found by Werker &
Fahn (1982) for Inula crithmoides and I. graveolens,
and by Werker et al. (1994) for Artemisia dracunculus,
on the chemical nature of the secretory product, are
similar to those of S. rebaudiana. Lipids were reported
for Chrysanthemum morifolium cv. Dramatic (Vermeer
& Peterson 1979b), whereas lipids, as well as
noncellulosic polysaccharides and proteins, were
reported for Inula viscosa (Werker & Fahn 1981, 1982).
In
Artemisia campestris ssp. maritima
(Ascensão & Pais 1987) and A. nitida (Corsi &
Nencioni 1995), the secretion is an oleoresin
composed of terpenoids, fatty acids, flavonoids and
alkaloids in the former species, and terpenoids,
steroids and sesquiterpene lactones in the latter.
Presence of sesquiterpene lactones in the secretory
product is mentioned for Artemisia nova (Kelsey &
Shafizadeh 1980) and A. umbelliformis (Cappelletti et
al. 1986). Such compounds were also found in extracts
of aerial parts of some species of Stevia, by Zdero et
al. (1991) and Hernández et al. (1997).
All head cells of the mature biseriate glandular
trichomes of S. rebaudiana contain starch grains.
This is, probably, the first report of occurrence of
starch in head cells of this kind of glandular trichome.
In Artemisia annua L. that compound is formed only
in the stalk cells (Duke & Paul 1993). Phenolic
substances were also detected in the trichome head
cells.
Secretory substances, including those released
by glandular trichomes, are thought to protect plants
against herbivores and pathogens; also they would
reduce the water loss by cuticular transpiration, as
well as the leaf temperature, since the presence of
such substances may result in an increase of
reflectance from the leaf (Dell & McComb 1975, 1977,
Kelsey & Shafizadeh 1980, Werker & Fahn 1981,
Cappelletti et al. 1986, Jordaan & Kruger 1992, Duke
et al. 1994, Tattini et al. 2000). Sesquiterpene lactones,
already detected in aerial parts of plants of some
species of the genus Stevia (Zdero et al. 1991,
Hernández
et al. 1997) might be among the
substances composing the material produced by the
glandular trichomes of S. rebaudiana. If present, such
compounds should be of some importance in the
protection of the plants. However, only the results
from a detailed chemical study of the secretory material,
and observations on plants growing in their natural
habitat, can give the investigators a solid basis for
speculations about the real function(s) of such
trichomes.
Acknowledgements - Our thanks to: Dr. Lilian B.P. Zaidan (Instituto de Botânica, São Paulo City, São Paulo, Brazil) for providing seeds; Dr. Mauro Alvarez (Fundação Universidade Estadual de Maringá, Maringá City, Paraná, Brazil) for improving, in various ways, our knowledge on the stevioside; Mr. João M. Catarin (Ingá Stevia Industrial S/A, Maringá City, Paraná, Brazil) for furnishing seeds and literature on plant cultivation; Mrs. M. Ester S. Silva for photographic work.
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